Means for compatibly reproducing video discs recorded according to different broadcast standards

ABSTRACT

A rotary recording medium reproducing apparatus reproduces a recorded signal from a rotary recording medium by use of a reproducing element. The rotary recording medium is recorded with at least a first carrier signal which is modulated by an information signal having a synchronizing signal of a predetermined frequency. The reproducing apparatus comprises a motor for rotating the rotary recording medium, a reference signal generating circuit for generating a reference signal having a frequency equal to a horizontal scanning frequency of a video signal of a standard television system which is characteristic of the reproducig apparatus and should originally be reproduced, or equal to 1/M (M is an integer) times the above horizontal scanning frequency, a detecting circuit for detecting a signal respective of the rotational speed of the rotary recording medium, and a comparator for comparing the reference signal and the signal respective of the rotational speed of the rotary recording medium, to control the rotational speed of the rotary recording medium by a compared output signal thus obtained, so that the synchronizing signal within the reproduced signal is reproduced at a frequency equal to the horizontal scanning frequency of the above standard television system with which the reproduction should originally be performed.

BACKGROUND OF THE INVENTION

The present invention relates generally to apparatuses for reproducing avideo signal of a certain system recorded on a rotary recording mediumas a video signal of a different system. More specifically, theinvention relates to an apparatus for reproducing a video signalrecorded on a rotary recording medium as a video signal of one out of aplurality of different systems which are classified according todifference in the field frequency and the number of horizontal scanninglines as a video signal substantially of another system.

At present, there are two principal video signal systems for television.One system, used in the United States, Japan, and other countries(hereinafter referred to as the "first standard system" or the "firstsystem") is based on a field frequency of 60 Hz (precisely speaking,59.94 Hz in the case of a color video signal) with a number ofhorizontal scanning lines of 262.5 lines within one field. The othersystem, used in Europe and other areas (hereinafter referred to as the"second standard system" or the "second system") is based on a fieldfrequency of 50 Hz with 312.5 horizontal scanning lines within onefield. There are various other systems such as those of combinations offield frequencies and numbers of horizontal scanning lines within onefield of 50 Hz and 202.5 lines and 50 Hz and 409.5 lines. However, withthe full-scale spread of color broadcasting, the trend ofintensification is toward the above mentioned first and second standardsystems.

As is known, video signal systems can be further classified by the modeof transmission of the chrominance signal as the NTSC system, the PALsystem, and the SECAM system in addition to the above describedclassification based on differences in field frequency and number ofhorizontal scanning lines within one field. With respect to thisdifference in mode of transmission of the chrominance signal, mutualconversion can be carried out with relative ease by an electricalprocess.

However, so-called system conversion, wherein field frequency and numberof horizontal scanning lines within one field are converted, hasheretofore required very complicated and elaborate apparatus. Morespecifically, the necessity for so-called system conversion, whereinfield frequency and number of horizontal scanning lines are converted,has heretofore been primarily a problem mutually between broadcastingstations or networks as in international relay broadcasting betweendifferent regions (for example, between Europe and the United States).For this reason, it has been necessary to carry out this systemconversion in a manner to meet very strict standards. Consequently,elaborate and large-scale electronic conversion apparatuses have beenemployed.

In an advanced electronic conversion apparatus being used at present, asystem by which a video signal is once converted into a digital signal,which is then stored in a digital memory of large capacity, subsequentlyread out in a required sequence, and restored into the original videosignal is used. By manipulating the time ratio of this signal storingand reading out, conversion of field frequency and number of horizontalscanning lines is accomplished. This electronic conversion apparatus,however, is disadvantageously elaborate and expensive.

On the other hand, a reproducing apparatus has been reduced to practice,which is adapted to reproduce a video signal recorded on a rotaryrecording medium (so-called video disc, and hereinafter simply referredto as a "disc") in a reproducing system such as an electrostatic or anoptical reproducing system. The disc reproducing apparatus onlyreproduces a standard video signal which is recorded on the disc.Accordingly, it is not necessary for the modulation format of achrominance signal to conform to the NTSC system, the PAL system, or theSECAM system. It is sufficient to convert the chrominance signal into apredetermined modulation format which conforms to a television system ofa television receiver, when the disc reproducing apparatus produces andsupplies the standard color video signal to the above televisionreceiver. Hence, by incorporating a conversion device for obtaining aspecific carrier chrominance signal of the NTSC system, the PAL system,or the SECAM system, in the disc reproducing apparatus, the discreproducing apparatus can be made compatible with respect to anotherreproducing apparatus having a different chrominance signal transmissionformat.

Therefore, compatibility of the disc reproducing apparatus can beobtained by considering the difference in the chrominance signaltransmission format described above. Since the difference between thehorizontal scanning frequencies in differing television systems is 0.7%which indicates that the horizontal scanning frequencies areapproximately equal, the horizontal scanning frequency within the discreproducing signal can be reproduced at an original horizontal scanningfrequency by the disc reproducing apparatus, by controlling therotational speed of the disc. Thus, the rotational speed of the disc wasconventionally controlled by performing a servo operation so that thefrequencies of the reference signal in a turntable servo circuit and thereproduced horizontal synchronizing signal, respectively coincide.However, in this conventional apparatus, a predetermined servo operationcould not be performed when the rotational speed of the disc was notclose to the regular rotational speed.

SUMMARY OF THE INVENTION

Accordingly, a general object of the present invention is to provide anovel and useful disc reproducing apparatus in which the above describedproblems have been overcome.

Another and more specific object of the present invention is to providea disc reproducing apparatus capable of reproducing a disc in which avideo signal of a television system other than a television system of avideo signal which is to be originally reproduced by the discreproducing apparatus, by performing a predetermined servo operationeven when the rotational speed of the disc is not close to the regularrotational speed of the disc. According to the disc reproducingapparatus of the present invention, reproduction can be performedwithout modifying the present television receiver, and maintainingcompatibility with other reproducing apparatuses in a state where noinconveniences are introduced with respect to practical use.

Still another object of the present invention is to provide a discreproducing apparatus in which the rotational speed of a rotary shaft ofa motor for rotating a disc of an constant-angular velocity system isdetected, and the rotational speed of the disc is controlled by a signalobtained by comparing the above detected rotational speed and areference signal, to always reproduce the reproducing horizontalscanning frequency at a predetermined frequency.

Another object of the present invention is to provide a disc reproducingapparatus capable of reproducing a color video signal upon anyinterchanged-reproduction of a disc recorded with a color video signalof any horizontal scanning frequency, by commonly using a color signalprocessing circuit, 1H delay line for separating the luminance signaland the carrier chrominance signal, and the like within the reproducingapparatus, and controlling the rotational speed of the disc so that thereproducing horizontal scanning frequency is always reproduced at apredetermined frequency, where the disc is recorded with a carriersignal which is modulated by a signal obtained by multiplexing aluminance signal and a carrier chrominance signal having a colorsub-carrier frequency which is (2n-1/2)(n is an integer which isidentical within each television system) times the horizontal scanningfrequency.

Still another object of the present invention is to provide a discreproducing apparatus capable of reproducing an audio disc in which anaudio signal is pulse-code-modulated and recorded, by adding a simpleadapter to an apparatus which originally reproduces a disc recorded witha video signal.

Other objects and further features of the present invention will beapparent from the following detailed description when read inconjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a systematic block diagram showing one example of aconventional reproducing apparatus;

FIG. 2 is a systematic block diagram showing a first embodiment of areproducing apparatus of the present invention;

FIG. 3 is a systematic block diagram showing a second embodiment of areproducing apparatus of the present invention;

FIG. 4 is a diagram showing positional relationships between therecorded signals on the disc;

FIG. 5 is a systematic block diagram showing a third embodiment of areproducing apparatus of the present invention; and

FIG. 6 is a systematic block diagram showing a fourth embodiment of areproducing apparatus of the present invention.

DETAILED DESCRIPTION

In order to readily understand the present invention, the NTSC systemcolor television system (hereinafter referred to as the N system, andrepresented by a subscript n) based on a field frequency of 59.94 Hz(approximately 60 Hz) with 525 horizontal scanning lines within oneframe, and the PAL system color television system and the SECAM systemcolor television system (hereinafter refereed to as the P system, andrepresented by a subscript p) based on a field frequency of 50 Hz with625 horizontal scanning lines within one frame, are given as examples,and will be first described. The disc and the reproducing apparatus arerespectively distinguished depending on the color television systems. Adisc on which the N system color video signal has been recorded isdesignated by Dn, and another disc on which the P system color videosignal has been recorded is designated by Dp. As described above, thecarrier chrominance signal of the color video signal is not required tobe recorded in the N or P system. Further, a reproducing apparatusadapted for reproducing the video disc Dn to produce the N system colorvideo signal, is designated by Rn, and another reproducing apparatusadapted for reproducing the video disc Dp to produce the P system colorvideo signal, is designated by Rp.

In the N system color video signal, 1H (H represents one horizontalscanning period) is 63.5 μs, which has a difference of only 0.7%, whencompared with 64 μs which is 1H of the P system color video signal. Thismeans that, when the reproducing apparatus Rn is used to reproduce thevideo disc Dp, the apparatus Rn rotates the video disc Dp at a speedwhich is 0.7% higher than a specific speed, to reproduce the color videosignal so that the horizontal scanning frequency reproduced from thedisc Dp corresponds to that of the N system. This speed-up rotation ofthe video disc only results in the reproduction of the video disc Dphaving a one-hour program, by about 25 seconds earlier than the normalreproducing time. On one hand, if the reproduced horizontal scanningfrequency f_(H) is of the N system, the electric circuit of thereproducing apparatus Rn operates normally irrespective of the programcontent of the disc Dp, and no inconveniences are introduced.

In the video signal thus reproduced, the number of scanning lines perframe is 625 which corresponds to that of the P system color videosignal recorded on the disc Dp, and the field frequency becomes 0.7%higher than 50 Hz. Assuming that a commercially available N system colortelevision receiver is used as monitor for receiving and indicating theabove video signal, this television receiver is generally set to astandard frequency of 60 Hz, however, the receiver can generally beadjusted to a standard frequency of 50 Hz by a control knob provided ona front panel of the receiver. The television receiver thus adjustedreceives the video signal from the reproducing apparatus Rn andreproduces a picture which is somewhat expanded vertically, but is insynchronism with respect to both the horizontal and vertical directions.Accordingly, by controlling the rotational speed of the video disc Dp,the combination of the N system reproducing apparatus Rn and the Nsystem color television receiver is capable of performing reproductionwhich is not perfect but sufficiently practical for application.

Similarly, by rotating the video disc Dn at a speed which is slower thana specific speed by 0.7% to reproduce the color video signal having theP system horizontal scanning frequency, the time required to reproducethe program of the video disc takes about 25 seconds longer per one-hourprogram, and the reproduced picture is somewhat compressed verticallycompared to the normal picture. However, the combination of thereproducing apparatus Pp and the P system color television receiver iscapable of reproducing a picture which is sufficiently clear inpractical applications.

Hence, there was a conventional apparatus as indicated in FIG. 1, whichis adapted to control the rotation of the disc Dp (or Dn) so as toreproduce the recorded horizontal synchronizing signal at a specifichorizontal scanning frequency f_(Hn) (or f_(Hp)) determined by thereproducing apparatus Rn (or Rp). In FIG. 1, a color video signal pickedup and reproduced by a reproducing element 12 from a disc 11, issupplied through a head amplifier 13 to a band-pass amplifier 14,wherein a predetermined frequency component of the signal is filteredand amplified. The signal thus amplified, is then demodulated by ademodulation circuit 15, and thereafter, led out through an outputterminal 16 on one hand, and supplied to a synchronizing signalseparation circuit 17 on the other. A horizontal synchronizing signalobtained from the separation circuit 17 is supplied to a comparator 18wherein the signal is subjected to phase comparison with a referencesignal supplied from a reference signal generator 19. The referencesignal has a frequency equal to the specific horizontal scanningfrequency f_(Hn) (or f_(Hp)) determined by the reproducing apparatus Rn(or Rp). The comparator 18 thus generates an error signal respective ofthe phase difference.

The output error signal from the comparator 18 is applied to a motor 20for rotating a turntable. Therefore, the rotational speed of the disc 11is controlled so that the frequency f_(H) of the reproduced horizontalsynchronizing signal coincides with the frequency f_(Hn) (or f_(Hp)) ofthe reference signal.

Here, the color video signal recorded on the disc is a carrier signalwherein the carrier signal is frequency modulated, phase modulated, oramplitude modulated. Thus, in order to perform separation and filteringoperation at the band-pass amplifier 14, the disc 11 must rotate at aspeed near the normal rotational speed. Accordingly, the above describedapparatus wherein a servo control is not performed until the rotatingspeed of the disc approaches near the normal rotating speed, can hardlybe reduced into practice.

FIG. 2 is a systematic block diagram showing a first embodiment of anapparatus according to the present invention. In FIG. 2, those partswhich are the same as those corresponding parts in FIG. 1 are designatedby like reference numerals, and their description is omitted. A disc 21of the N system (or the P system) is recorded with a frequency dividedmultiplexed signal formed from a chrominance signal modulated by thecolor video signal, and a chrominance signal modulated by a frequencywhich is 1/M (M is an integer) times the horizontal scanning frequencyf_(Hn) (or f_(Hp)). A rotational speed control signal detection circuit22 is disposed in a signal path different from a color video signaldemodulation signal path, and operates to detect a rotational speeddetection signal from the reproduced signal. The rotational speedcontrol signal is a carrier signal modulated by a frequency which is 1/Mtimes the horizontal scanning frequency f_(Hn) (or f_(Hp)) and has toneburst waveform. The detection circuit 22 is adapted to detect theenvelope of the rotational speed control signal, which means that therotational speed control signal can be detected over a wider range ofrotrtional speeds of the P system (or N system) disc 21, that is, therotational speed control signal can be detected before the rotationalspeed of the disc approaches near the specific rotational speed.

The reference signal supplied from the reference signal generator 19 issubjected to a 1/M frequency division by a 1/M frequency divider 23, andis then supplied to the comparator 18, wherein the frequency dividedsignal is phase compared with the rotational speed control signaldetected by the rotational speed control signal detection circuit 22.The rotational speed of the motor 20 is controlled according to thephase difference thus obtained. Accordingly, the video disc 21 can becontrolled to the specific rotational speed at which the video disc 21,is reproduced at a horizontal scanning frequency of the N system (or theP system) disc even when the disc 21 is of the p system (or N system).

In the above described embodiment of the prevent invention, the integerM is assumed to be the same value irrespective of whether the system isa P or N system. Further, the rotational speed control signal which is areciprocal of an integer times the horizontal scanning frequency f_(Hn)(or f_(Hp)) is used because the lower frequency is advantageous in viewof factors such as mechanical response of the rotational servo.

Next, a modification of the first embodiment of the apparatus of thepresent invention will be described in conjunction with FIG. 2. In thepresent modification, the video disc recorded similarly as in the firstembodiment, is reproduced in a manner such that the rotational speedcontrol signal is periodically reproduced 5 or 25 times within one frameperiod. These numbers, that is, 5 and 25 are obtained by considering acommon divisor so that the frequency division ratio is the reciprocal ofan integer, since 525 scanning lines exist in the N system and 625scanning lines exist in the P system. When detecting the rotationalspeed control signal 5 times within one frame period, a signalrotational speed control signal is recorded every 105 (=525/5) scanninglines in the N system and every 125 (=625/5) scanning lines in the Psystem. Similarly, in the case where the rotational speed control signalis detected 25 times within one frame period, a single rotational speedcontrol signal is recorded every 21 scanning lines in the N system andevery 25 scanning lines in the P system.

Hence, in the present modification, frequency dividers 24 and 25, and achangeover switch 26 are provided instead of the frequency divider 23,as indicated in FIG. 2. When reproducing the video disc having 5 (or 25)rotational speed control signals recorded periodically within one frameperiod, in the P system disc Dp, the frequency division ratio 1/Mp ofthe frequency divider 24 is set to 1/125 (or 1/25), and a signal derivedtherefrom is supplied by way of the switch 26 to the comparator 18, andin the N system disc Dn, the frequency division ratio 1/Mn of thefrequency divider 25 is set to 1/105 (or 1/21), and a signal derivedtherefrom is supplied by way of the switch 16 to the comparator 18.Accordingly, the discs Dp and Dn can be reproduced interchangeably.

FIG. 3 is a systematic block diagram showing a first embodiment of anapparatus according to the present invention. In FIG. 3, those partswhich are the same as those corresponding parts in FIG. 2 are designatedby like reference numerals, and their description is omitted.

The apparatus of the present embodiment is suitable for a constantangular velocity system (CAV system) disc.

The CAV system disc is different from the constant linear velocitysystem (CLV system) and is recovered with the synchronizing signalsaligned towards the center of the disc. For example, in a CAV systemdisc having four fields of color video signals per rotation, thevertical synchronizing signals are recorded aligned toward the center ofthe disc at positions indicated by 33₁ -33₄ in FIG. 4. Accordingly, bycontrolling the rotational frequency of a rotary shaft of the motor forrotating the disc, it is possible to equivalently set the reproducedhorizontal scanning frequency to a predetermined value.

In FIG. 3, a disc 27 and disc-shaped gear wheel 28 made of magnet whichrotate unitarily together with the rotary shaft of the motor 20, aresupported on a rotary shaft of the motor 20. A magnetic detector 29 isdisposed to confront the gear wheel 28, and operates together with thesame gear 28 to detect the rotational speed of the motor. The gear 28 isprovided with tooth periodically at equal angular intervals. Every timewhen each teeth of the gear wheel 28 passes by the magnetic detector 29,the magnetic detector 29 produces a single pulse. As means for detectingthe rotational speed of the motor 20, instead of the magnet gear wheel28 and the magnetic detector 29, various known devices may be adopted inwhich, for example, a disc having many slits along the peripheraldirection is fixed to the rotary shaft of the motor 20, and therotational speed is detected in accordance with the frequency of thelight which is allowed to pass through the slits intermittently.

In the case where the disc 27 is recorded with four fields of colorvideo signal per one complete turn as indicated in FIG. 4, therotational speed of the motor 20 is set at 900 rpm for the disc Dn, andat 750 rpm for the disc Dn. The number of scanning lines recorded perone complete turn is 1050 for the disc Dp, and 1250 for the disc Dn. Thecommon divisor of 1050 and 1250 are 2, 10, 25 and 50 (excluding 1).Accordingly, if the number of teeth of the gear wheel 28 is selected atone of the above listed five kinds of numbers, a relationship betweenthe number of pulses generated from the magnetic detector 29 per onecomplete turn of the rotary shaft of the motor 20, and the number ofscanning line per single pulse, and a relationship between thereproducing apparatus and the type of video disc to be reproduced,become as indicated in the following Table.

                  TABLE    ______________________________________    Repro-        Number of Output Pulses from    ducing        Magnetic Detector 29 per one    Appa-         turn of the gear wheel    ratus  Disc   2       5    10    25  50    ______________________________________    Pn     Dn     525     210  105   42  21   Number of           Dp     625     250  125   50  25   scanning lines    Pp     Dn     525     210  105   42  21   per single           Dp     625     250  125   50  25   output pulse    ______________________________________

As apparent from the above Table, the number of scanning lines persingle output pulse of the magnetic detector 29, is determined bywhether the disc is Dn or Dp, irrespective of the system of thereproducing apparatus. Accordingly, as indicated in FIG. 3, frequencydividers 30 and 31 are connected in parallel at the output side of thereference signal generator 19. The frequency division ratio 1/Mn of thefrequency divider 30, is set at a value equal to a repetition frequencyof the output pulse of the magnetic detector 29, when reproducing the Nsystem disc Dn. When the number of teeth of the gear wheel 28 is 50, forexample, the frequency division ratio of the frequency divider 30 is setat 1/21. Further, the frequency division ratio 1/Mp of the frequencydivider 31 is set at a value equal to a repetition frequency of theoutput pulse of the magnetic detector 29 when reproducing the P systemdisc Dp. For example, when the number of the teeth of the gear wheel 28is 50, the frequency division ratio is set at 1/25. The switch 32 ismanually or automatically changed over so that the output of thefrequency divider 30 is supplied to the comparator 18, when the disc Dnis to be reproduced and so that the output of the frequency divider 31is supplied to the comparator 18, when the disc Dp is to be reproduced.Accordingly, the rotational speed of the motor 20 is thereby controlledso that the horizontal scanning frequency reproduced from the disc 27coincides with a predetermined horizontal scanning frequency. As aresult, the reproducing apparatus Rn (or Rp) can reproduce the disc Dp(or Dn).

When the number of teeth of the gear wheel 28 is large, this generallyimproves the rotational speed controlling capability, but is difficultto manufacture in actual practice. The number of gear teeth "50"indicated at the right most column in the above Table is preferable inview of both performance and machining operation, and is most suitablefor the apparatus of the present invention.

If the disc is of the CAV system, and is recorded with two fields ofcolor video signal per one track turn, the gear wheel 28 which has 5 or25 gear teeth is used. In addition, the frequency division ratio of thefrequency dividers 30 and 31, are respectively set at 1/105 and 1/125for a 5-teeth gear wheel, and at 1/21 and 1/25 for a 25-teeth gearwheel.

In this embodiment of the invention, since the rotational speed of thedisc is detected by detecting the rotational speed of the motor 20, itis advantageous in that the rotational speed of the disc can be rapidlycontrolled to the predetermined rotational speed without picking up andreproducing the disc 27 by means of the reproducing element. Theembodiment of the invention may be modified, similar to the case of themodification of the first embodiment, in a manner such that two types ofoscillators for generating their specific repetition frequencies replacethe circuit comprising the reference signal generator 19, and thefrequency dividers 30 and 31.

Next, a third embodiment of the apparatus of the present invention willbe described. According to the present embodiment of the invention, in adisc recording and reproducing system wherein the luminance signal andthe carrier chrominance signal are multiplexed and the signal thusmultiplexed modulates carrier to be recorded on the disc and reproducethe signal thus recorded from the disc, in order to establish arelationship where the multiplexed luminance signal and the carrierchrominance signal undergo frequency interleaving with each other, acolor sub-carrier frequency f_(c) of the carrier chrominance signal isselected at a frequency which is an odd-number multiple of 1/2 thehorizontal scanning frequency, and further, an odd-number multiple of1/2 the horizontal scanning frequency assumes the same value for the Psystem disc Dp and the N system disc Dn. Specifically, the colorsub-carrier frequency f_(cp) of the carrier chrominance signal of thedisc Dp is selected at 2n-1/2·f_(Hp), and the color sub-carrierfrequency f_(cn) of the carrier chrominance signal of the disc Dn isselected at 2n-1/2·f_(Hn), where 2n-1/2 is 162.5, for example.

In such cases where the disc Dp thus recorded is reproduced by thereproducing apparatus Rp, and where the disc Dn is reproduced by thereproducing apparatus Rn, both the reproduced horizontal scanningfrequency and the color sub-carrier frequency are different depending onthe above cases. Therefore, the reproducing apparatuses Rs and Rnrespectively have standard reproducing circuits different from eachother. In a case where the reproducing apparatus Rn reproduces the discDp, the rotational speed of the disc is controlled so that thehorizontal synchronizing signal which has been recorded is reproduced asnot of the frequency f_(Hp) but of the frequency f_(Hn). Accordingly,the reproduced carrier chrominance signal has a color sub-carrierfrequency of 2n-1/2·f_(Hn) and not of 2n-1/2·f_(Hp), and therefore isequivallent to the carrier chrominance signal of the N system disc whichcan be reproduced by means of the reproducing apparatus Rn. That is, thereproducing apparatus Rn reproduces the carrier chrominance signal at afrequency equal to the N system carrier chrominance signal, which meansthat it is not necessary to modify a chrominance processing circuit inthe reproducing apparatus Rn. The result is also the same in the casewherein the reproducing apparatus Rp reproduces the disc Dn. That is,the reproducing apparatus Rp reproduces the carrier chrominance signalat a frequency equal to that of the carrier chrominance signal of the Psystem.

FIG. 5 is a systematic block diagram showing a third embodiment of theapparatus of the invention described above. In FIG. 5, those parts whichare the same as or equivalent to corresponding parts in FIG. 1 aredesignated by like reference numerals and will not be described again indetail.

Referring to FIG. 5, a disc 34 is recorded with a signal within thecarrier chrominance signal having a color sub-carrier frequency of2n-1/2·f_(Hp) (or 2n-1/2·f_(Hn)) multiplexed with the luminance signal,and the carrier is subjected to, for example, frequency modulation withthe signal thus multiplexed. This disc 34 is rotated by a motor 20 underthe control of a signal for controlling the rotational speed, which issupplied thereto from a terminal 43. The FM demodulator 35 produces ademodulated signal, which is a multiplexed signal formed from theluminance signal and the carrier chrominance signal which are arrangedso as to interleave with each other with respect to horizontal scanningfrequency. Additionally, both the horizontal scanning frequency and thecolor sub-carrier frequency of the demodulated signal, are respectivelyequal to corresponding frequency of the television system which is to beoriginally reproduced by the same reproducing apparatus. Accordingly, inboth cases where the discs Dn and Dp are reproduced, a 1H delay line 37which constitutes a separation circuit, can be used in common. The 1Hdelay line is generally of high precision, and cannot be used in commonfor both the N system and the P system, even though the differencebetween the horizontal scanning frequencies of the N and P systems isonly about 0.7%. In contrast, the present embodiment of the inventionenables the 1H delay line to be used in common due to the reasons setforth above.

Signals introduced to and led out from the 1H delay line 37 are added atan adder 38 thereby to produce the luminance signal. On the other hand,signals introduced to and led out from the 1H delay line 37 aresubtracted from each other at a subtractor 39 thereby to produce thecarrier chrominance signal. This carrier chrominance signal, asdescribed above, is not a signal modulated by a specific modulationsystem of the NTSC system, the PAL system, or the SECAM system, but is asignal wherein the color sub-carrier frequency is subjected to 9 carriersuppressing right-angle two-phase modulation, for example, by use of,two color difference signals. The carrier chrominance signal producedfrom the subtractor 39 is supplied to a television system converter 40,where it is converted to the carrier chrominance signal which conformsto a specific television system, and is then supplied to an adder 41,where it is multiplexed with the reproduced luminance signal from theadder 38 to produce a standard color video signal of the above specifictelevision system. This color video signal is led out through an outputterminal 42 and is fed to the television receiver for monitoring.

According to the present embodiment, three kinds of reproducingapparatus, are prepared in accordance with the chrominance signaltransmission modes, that is, the NTSC system, the PAL system, and theSECAM system reproducing apparatuses, while two kinds of discs, that is,the N system disc and the P system disc exist. When the disc Dp isreproduced by the SECAM system reproducing apparatus, it produces thenormal standard color video signal conforming to the SECAM systemstandards. In the case where this SECAM system reproducing apparatusreproduces the disc Dn, the reproduced horizontal scanning frequency isexactly the same as that of the SECAM system. Only the field frequencybecomes 59.5 Hz which is higher by about 20% above the normal frequency50 Hz, but the commercially available SECAM system color televisionreceiver is generally capable of synchronizing with the above fieldfrequency of 59.5 Hz. Further, the carrier chrominance signalreproduced, is exactly the same as that of the SECAM system.Accordingly, the SECAM system can receive the reproduced signal withoutaccompanying any difficulties. Similar to the preceding case, the PALsystem reproducing apparatus and the NTSC system reproducing apparatusare also capable of reproducing two kinds of discs interchangeably.

In the meanwhile, there exists a disc having a tracking control signalwhich is recorded on each track or between tracks adjacent each other,and the frequency range of which is outside that of the carrier of thevideo signal. This tracking control signal is reproduced by thereproducing element and causes the reproducing element to be controlledso as to follow and trace the track. For example, a disc has beenproposed wherein first and second reference signals f_(T1) and f_(T2)for tracking control (hereinafter referred to as "tracking signals")having frequencies lower than the frequency range of the carrier of thevideo signal and are mutually different, are recorded, where thetracking signals are changed over every one complete rotation period ofthe disc. A sub-track is formed at an intermediate part between adjacentrecorded tracks, in a burst form, and further, a third tracking signalf_(T3) for changing over tracking polarities of the tracking servocircuit is recorded, with levels being less than a predetermined levelso as not to have a deterimental effect on the video signalreproduction, on the video signal recorded track adjacent to positionwhere disposition of f_(T1) and f_(T2) are changed over (these positionsare selected at one position among four positions of the verticalblanking period of time when four-fields of the video signal is recordedper one complete rotation of the disc).

In the apparatus of the present invention, frequencies of the trackingsignals f_(T1), f_(T2) and f_(T3) are respectively selected at valueswhich are real number multiples of the horizontal scanning linefrequency f_(Hp) or f_(Hn). Here, the real number is not required to bean integer or an odd-multiple of 1/2, because an appropriate band-passfilter may be used for separating the tracking signals f_(T1), f_(T2),and f_(T3) from each other. However, since circuit arrangement of thedisc reproducing apparatus may induce possible beat due to infiltrationof the tracking control signal into the video signal, it is preferred toselect the frequency of the tracking signals to a frequency which is anodd-number multiple of the frequency f_(H) or f_(H) /2.

By selecting the frequency of the tracking control signals as set forthabove, when either disc Dn or Dp is reproduced at horizontal scanningfrequencies of the reproducing apparatus Rn and Rp, the tracking signalsare also reproduced at frequencies based on the reproducing apparatus Rnand Rp. Accordingly, it is not necessary to change over the trackingsignal discrimination circuit according to the types of the video discto be reproduced.

Moreover, according to the apparatus of the present invention, therotational speed of the disc is controlled so as to always reproduce thehorizontal scanning frequencies f_(Hn) or f_(Hp) determined by the discreproducing apparatus, irrespective of which of the discs Dn and Dp areto be reproduced. Therefore, when recording an information signal otherthan the video signal on the discs, the information signal is recordedat a frequency which is a real-number (being an arbitrary value but thesame value in each case) multiple of the horizontal scanning frequencyf_(Hn) of f_(Hp) for discs Dn and Dp. Accordingly, in either case wherethe discs Dn or Dp is reproduced by the same reproducing apparatus, acircuit for frequency selecting the above information signals can beused in common.

As an example of the above described information signal, there aresignals other than the tracking signals. Firstly, there is a PCM signalin which the track number, program number, time and the like aresubjected to pulse code modulation (PCM) and recorded within thevertical blanking period of the standard video signal for the purpose ofdisplaying the track number being reproduced and cueing a desiredprogram. Secondly, there is an audio signal accompanied by the standardvideo signal.

Here, by selecting the clock frequency of recording PCM signal to avalue which is the same real-number multiple of the frequency of thehorizontal synchronizing signal which is to be recorded on the videodisc, the PCM signal is reproduced at the same clock frequency,irrespective of which of the discs Dp and Dn is reproduced, whereby thesame PCM signal reproducing circuit can be used in common. When clockreproduction is taken into consideration, an integer multiple ispreferred as compared to a real-number multiple. In the case where PCMis of a clock self-reproduction type, such as bi-phase, space, codemodulation system, any arbitrary real-number multiple may be adoptedwithout difficulty.

The audio signal is used as either monophonic, stereophonic, orbilingual sound. For this purpose, one or two sub-carriers are subjectedto FM, AM, or PM modulation with the audio signal, and the signal thusmodulated is multiplexed with the standard television system videosignal (standard video signal), while another carrier is modulated withthe signal thus multiplexed and is recorded on the disc. In thisconnection, the frequency of the sub-carrier for an audio carrier isselected at a value which is the same real-number multiple of thefrequency f_(Hn) or f_(Hp) of the horizontal synchronizing signal whichis to be recorded on the disc. An odd-number multiple of f_(Hn) /2 orf_(Hp) /2 is preferred when beat interference and the like are takeninto consideration. Also, in this case, the discs Dn and Dp arereproduced at the same frequency, whereby a filter for discriminatingthe audio sub-carrier can be used in common. Additionally, it ispossible to record the signal wherein the audio sub-carrier ismultiplexed with the carrier modulated with the standard video signal.In this case, the audio sub-carrier may be selected to the samereal-number multiple of the frequency f_(Hn) or f_(Hp).

Furthermore, when recording the carrier which is frequency modulatedwith the standard video signal on the video disc, a carrier frequencycorresponding to the pedestal level of the video signal and/or anothercarrier frequency corresponding to the peak level of the synchronizingsignal are selected to a value which is a real-number multiple of thehorizontal scanning frequency f_(Hn) or f_(Hp) of the standard videosignal, where the real-number is the same for both the discs Dn and Dp.Accordingly, similar to the above case, the disc reproducing apparatusRn and Rp can respectively reproduce discs Dp and Dn of a differentsystem at a frequency inherent to the disc reproducing apparatus underoperation. If the horizontal scanning frequency of the video signal isnot selected as set forth above, the pedestal level and the peak levelof the synchronizing signal undergo change depending on the disc whichis to be reproduced, which may cause trouble upon reproduction of adirect current component of the video signal. The pedestal levelfrequency and the synchronizing signal peak level frequency can be of areal-number multiple of the frequency f_(Hn) or f_(Hp), but it ispreferable to set them to an odd-number multiple of the frequency f_(Hn)/2 or f_(Hp) /2, because the FM signal has a relatively higher energylevel at the pedestal level and the synchronizing signal peak level.

The embodiments described above are all directed to the video disc. Nextto be described is an embodiment which is adapted to reproduce a rotaryrecording medium recorded with pulse code modulated audio signal asvariations in geographical shapes thereon. (hereinafter referred to as"audio disc"), in addition to the video disc.

As has been described above, the CAV system apparatus of the presentinvention should be arranged so that the motor rotates at rotationalspeeds within a predetermined range depending on the video disc Dn orDp, which thereby ensures that the reproduced horizontal scanningfrequency, coincides with the horizontal scanning frequency inherent tothe reproducing apparatus under operation. In order to meet thisrequirement, the present embodiment is arranged so that, based on eitherthe PCM clock frequency of the audio disc or a frequency of onoscillator for forming the clock signal, is formed into a signal havinga frequency near the frequency f_(Hn) or f_(Hp). This signal is usedinstead of the output reference signal of the reference signal generator19 indicated in FIG. 3. Accordingly, similar to the embodiment indicatedin FIG. 3, the motor can be controlled so as to rotate at apredetermined rotational speed, as long as the rotational speed of theaudio disc falls within the above described range, and the PCM signalthus reproduced is generated with a predetermined clock signal.Therefore, the disc reproducing apparatus can be modified into an audiodisc reproducing apparatus only with the addition of a simple adapter.

By selecting the data rate or clock frequency of the PCM signal recordedon the audio disc at the frequency which is K/M (K and M are integers)times the frequency f_(Hn) or f_(Hp), or a frequency in the vicinitythereof. Further, by using the frequency f_(Hn) or f_(Hp), or afrequency in the vicinity thereof, it becomes possible to obtain the PCMreproducing signal having a predetermined data rate or clock frequency.Moreover, by using the above described adapter, the reproducingapparatuses Rn and Rp can respectively obtain the same rotational speed.

The adapter may be either be separated from the reproducing apparatus orincorporated inside the reproducing apparatus.

FIG. 6 is a systematic block diagram showing a fourth embodiment of theapparatus which can operate also as audio disc reproducing device. InFIG. 6, those parts which are the same as corresponding parts in FIG. 2are designated by like reference numerals and will not be describedagain in detail. A reference numeral 44 disgnates either an audio discor a video disc recorded with the rotating speed controlling signal.When the audio disc is to be reproduced, change-over switches 45 and 53are respectively connected to an adapter 52. The audio disc has beenrecorded with a time divided and multiplexed signal comprising the PCMsignal and a synchronizing signal which has been subjected to PCM forevery period of f_(Hp) or f_(Hn), or a multiple of the reciprocal of aninteger of f_(Hp) or f_(Hn) (the overall data rate of the PCM signalbeing an integral multiple of the reciprocal of an integer of f_(Hn) orf_(Hp)). The reproduced signal of the audio disc is supplied to asynchronizing signal detector 46, a clock reproduction circuit 49 and adata-processing circuit 50 within the adapter 52.

The synchronizing signal detector 46 detects the above described PCMsynchronizing signal. The signal thus detected is supplied by way of thechange over switch 45 to the comparator 18, where it is compared with asignal, which is obtained by causing an output signal of an originaloscillator 47 to pass through a frequency divider 48 with frequencydivision ratio of 1/K, and thereby has a frequency equal to that of thesynchronizing signal. Respective to a signal from the comparator 18, themotor 20 is controlled so that the PCM signal having the predeterminedclock frequency is reproduced from the audio disc.

The PCM signal thus reproduced is demodulated in a known method by meansof the clock reproduction circuit 49 supplied with both the output ofthe synchronizing signal detector 46 and the output of the originaloscillator 47, and the data processing circuit 50, and normal audiosignal is thereby led out through an output terminal 51.

Further, this invention is not limited to these embodiments but variousvariations and modifications may be made without departing from thescope of the invention.

What is claimed is:
 1. A rotary recorded medium which has a video signalpre-recorded thereon in any of at least two formats, both of saidformats being reproducible on a reproducing system designed around anyof said formats, a first of said formats being a medium pre-recorded ata first rotational speed with a first video signal which is compatiblewith a television receiver of a first television broadcasting standard,said first format having a first horizontal scanning frequency f_(H1)and a first frame frequency, a second of said formats being a mediumpre-recorded at a second rotational speed with a second video signalwhich is compatible with a television receiver of a second televisionbroadcasting standard, said second format having a second horizontalscanning frequency f_(H2) and a second frame frequency, a first systemreproducing apparatus primarily designed for use with the televisionreceiver of said first television broadcasting standard comprising firstmeans for rotating said first format recorded medium at said firstrotational speed for reproducing the first video signal having saidfirst horizontal scanning frequency f_(H1) for the television receiverof said first television broadcasting standard, the first rotating meansin said first system reproducing apparatus rotating said second formatrecorded medium to reproduce said second video signal at a scanningfrequency equal to said first horizontal scanning frequency f_(H1) forthe television receiver of said first television broadcasting standard,a second system reproducing apparatus primarily designed for use withthe television receiver of said second television broadcasting standardcomprising second means for rotating said second format recorded mediumat the second rotational speed for reproducing the second video signalhaving said second horizontal scanning frequency f_(H2) for thetelevision receiver of said second television broadcasting standard, thesecond rotating means in said second system reproducing apparatusrotating said first format recorded medium to reproduce said first videosignal at a scanning frequency equal to said second horizontal scanningfrequency f_(H2) for the television receiver of said second televisionbroadcasting standard, said first format recorded medium having a firstcarrier chrominance signal pre-recorded thereon, said first carrierchrominance signal having a first chrominance subcarrier frequencyf_(c1) equal to kf_(H1), where k is a real number, and said secondformat recorded medium having a second carrier chrominance signalpre-recorded thereon, said second carrier chrominance signal having asecond chrominance subcarrier frequency f_(c2) equal to kf_(H2) so thatboth the first and second format recorded mediums are playable on bothsaid first and second system reproducing apparatuses.
 2. The rotaryrecorded medium as claimed in claim 1, in which said real number k isequal to (2n-1)/2, where n is a positive integer.
 3. The rotary recordedmedium as claimed in claim 1, in which said first format recorded mediumhas a first signal which is pre-recorded at a first rotational speed,said first pre-recorded signal including a control signal having afrequency which is equal to either the first horizontal scanningfrequency f_(H1) or a reciprocal of an integer times the horizontalscanning frequency f_(H1), and said second format recorded medium has asecond signal which is pre-recorded at a second rotational speed, saidsecond pre-recorded signal including a control signal having a frequencywhich is equal to either the second horizontal scanning frequency f_(H2)or a reciprocal of an integer times the horizontal scanning frequencyf_(H2).
 4. The rotary recorded medium as claimed in claim 1, on which arotational speed control signal is pre-recorded in a burst manner, thebursts of control signals being a number per frame period of the videosignal which is equal to a common divisor of horizontal scanning linenumbers of said first and second television broadcasting standards. 5.The rotary medium as claimed in claim 1, on which the video signal ispre-recorded in a form of a frequency modulated carrier, aninstantaneous frequency of the carrier corresponding to the pedestallevel of the video signal or corresponding to the peak level of ahorizontal synchronizing signal of the video signal being m times eachof the first and second horizontal scanning frequencies, where m is areal number.
 6. A reproducing apparatus primarily designed for playing afirst format recorded medium which is pre-recorded at a first rotationalspeed, the first format comprising a first video signal having a firsthorizontal scanning frequency f_(H1) resulting in m frames of the firstvideo signal, each frame in said first format having a first number ofscanning lines and being pre-recorded on one track turn of said firstformat recorded medium, where m is an integer, said first formatrecorded medim rotating at the first regular rotational speed so thatsaid first horizontal scanning frequency f_(H1) is reproduced unchanged,said apparatus also playing a second format recorded medium in place ofthe first format recorded medium which second format recorded medium ispre-recorded at a second rotational speed, the second format comprisinga second video signal having a second horizontal scanning frequencyf_(H2) resulting in .[.m.]. .Iadd.n .Iaddend.frames of the second videosignal, each frame in said second format having a second number ofscanning lines and being pre-recorded on one track turn of said secondformat recorded medium, .Iadd.where n is an integer, .Iaddend.saidsecond format recorded medium rotating to reproduce said second videosignal at a horizontal scanning frequency equal to said first horizontalscanning frequency f_(H1), said reproducing apparatus comprising: meansfor generating a number of rotation detection pulses for every onerevolution of said rotary recorded medium, said number being equal to adivisor which is common to said first and second numbers of horizontalscanning lines; means for generating a reference signal having afrequency which is obtained by dividing the first horizontal scanningfrequency f_(H1) by the first number of horizontal scanning lines on onetrack .Iadd.turn .Iaddend.of said first system recorded medium and thenmultiplying said common divisor with the quotient; and means forcomparing the frequency of the generated reference signal and thefrequency of the rotation detection pulses and for controlling therotational speed of said rotary recorded medium so that the twofrequencies being compared become equal to each other.
 7. Thereproducing apparatus as claimed in claim 6, in which said recordedmedium has a rotational speed control signal pre-recorded thereon, saidrotational speed control signal being reproduced, and said means forgenerating a number of rotation .[.detetion.]. .Iadd.detection.Iaddend.pulses responding to said reproduced rotational speed controlsignal, to generate said rotation detection pulses.
 8. The reproducingapparatus as claimed in claim 6, in which said recorded medium has saidvideo signal pre-recorded in a constant angular velocity system, andsaid means for generating a number of rotation detection pulses is arotational speed detecting pulse generating means for obtaining arotational speed detecting pulse in response to the rotational speed ofsaid rotary recorded medium.